CN113196537B

CN113196537B - Apparatus for manufacturing cell stack of secondary battery

Info

Publication number: CN113196537B
Application number: CN201880100340.8A
Authority: CN
Inventors: 金容成; 金成哲; 李娜拉; 韩龙燻; 金京燮
Original assignee: LG Electronics Inc
Current assignee: LG Electronics Inc
Priority date: 2018-12-19
Filing date: 2018-12-19
Publication date: 2024-03-22
Anticipated expiration: 2038-12-19
Also published as: CN113196537A; KR20210098538A; WO2020130184A1

Abstract

The battery stack manufacturing apparatus of a secondary battery according to an embodiment of the present invention includes: a lamination stage mounted to be capable of reciprocating in a horizontal direction and a vertical direction; a diaphragm supply portion positioned above the lamination stage so as to supply a diaphragm onto the lamination stage; a first multi-head part respectively provided at an upper portion of one side of the lamination stage such that the electrode plates are positioned in alignment with the separator positioned on the lamination stage that has been moved to one side, and then laminated one by one therewith; a second multi-head portion provided at an upper portion of the other side of the lamination stage such that a position of an electrode plate is aligned with a separator positioned on the lamination stage that has been moved to the other side, and then laminated thereto one by one; and a defect inspection portion provided between the first multi-head and the second multi-head, the defect inspection portion capturing an image of a cell stack laminated on the lamination stage every time the lamination stage moves between the first multi-head and the second multi-head, thereby determining whether the cell stack is defective based on cell stack image information.

Description

Apparatus for manufacturing cell stack of secondary battery

Technical Field

The present disclosure relates to a cell stack manufacturing apparatus for a secondary battery capable of manufacturing a cell stack at high speed and high precision.

Background

A secondary battery is a device that converts electric energy into chemical energy, stores the chemical energy, and generates electricity when needed, and both charging and discharging occur at one electrode, and an anode (negative electrode) and a cathode (positive electrode) are distinguished based on a discharging reaction.

The secondary battery includes: a positive electrode plate and a negative electrode plate coated with an active material on a current collector; a separator separating the positive electrode plate and the negative electrode plate; an electrolyte that transports ions through the separator; a case accommodating the positive electrode plate, the separator, and the negative electrode plate; and lead pieces connected to and led out of the positive electrode plates and the negative electrode plates.

Recently, in order to increase the battery capacity of the secondary battery, a method of increasing the number of electrodes or maximizing the size of the electrodes is required, and the battery of the secondary battery may be manufactured by a winding method, a folding method, and a stacking method.

In the winding method, the positive and negative electrode plates are placed on a separator, the separator is rolled up to form a jelly roll, and when the positive and negative electrode plates and the separator become large, defects may occur due to misalignment, so the winding method is mainly used to manufacture a small-sized secondary battery.

In the folding method, an adhesive is applied to both surfaces of a separator, a plurality of cut positive electrode plates and negative electrode plates of a predetermined size are attached to both surfaces of the separator at predetermined intervals, respectively, and then the separator is folded several times such that the positive electrode plates and the negative electrode plates are alternately arranged. Of course, an additional process of cutting the positive electrode plate and the negative electrode plate in advance and attaching them to the separator is required.

In the stacking method, a laminate form in which positive electrode plates or negative electrode plates are adhered to separators in a predetermined size is manufactured, and then the laminate is stacked to manufacture a battery stack form in which positive electrode plates, separators, negative electrode plates, and separators are alternately interposed.

The stacking method can flexibly control the number of stacks and can increase the density of the electrode with respect to the volume, compared to the winding method or the folding method. However, the stacking method has problems of low productivity and high production cost due to the process of adding the individual stacked laminated electrode bodies.

In korean patent No.313119 (filed on 1 month 26 1999), an electrode group of a secondary battery is disclosed in which a stacked structure is formed by being folded in a zigzag manner in a state in which a positive electrode, a negative electrode and a separator are overlapped.

In korean patent No.1220981 (filed on 3 th 2010), an electrode plate laminating apparatus for a secondary battery is disclosed, which comprises: a supply device for continuously supplying the sheet-like separator in the longitudinal direction; a fixing means for fixing an electrode plate stack formed by alternately stacking the separator and the electrode plates, the fixing means being located at a point spaced apart from the supplying means along a supplying direction of the separator; and a transfer means for further stacking the separator and the electrode plates on the electrode plate stack by moving the electrode plates such that after the electrode plates are in contact with one surface of the separator between the supply means and the fixing means, the other surface of the separator at a portion where the electrode plates are in contact is in contact with the electrode plate stack fixed to the fixing means.

As described above, the Z-stacking method is widely used in which the separator is folded in a zigzag manner and the positive electrode plates and the negative electrode plates are alternately stacked therebetween.

Of course, in order to prevent short circuits, the distance between the negative electrode plate and the positive electrode plate must be kept constant, and after the stack is manufactured, the stacked state should be checked, and if the stacked state is poor, the entire stack should be discarded.

However, according to the related art, even when the stack is inspected using a measuring device such as CT, there is a problem in that the defect rate of the stack is high because the position of the electrode plate cannot be precisely seen due to the separator. In addition, there is a problem in that productivity is lowered because the fully manufactured stack must be inspected to determine electrode plate defects and discard the entire stack.

Further, according to the related art, the electrode plate is brought into contact with one surface of the separator while the moving means horizontally moves, and then the other surface of the separator is brought into contact with the stack fixed to one side of the fixing means while the moving means rotates and moves, and in this process, the tension of the separator periodically varies. Therefore, production efficiency may be lowered because the separator may be torn when the separator is strained in the process, and there is a problem in that: when the separator is released in this process, it is difficult to secure the quality of the stack because the electrode plates cannot be stacked at the correct positions of the separator.

Disclosure of Invention

Technical problem

The present disclosure is designed to solve the problems of the prior art, and it is an object of the present disclosure to provide a stack manufacturing apparatus for a secondary battery capable of responding to a defect by recognizing the defect during the stack manufacturing.

It is another object of the present disclosure to provide a stack manufacturing apparatus for a secondary battery capable of uniformly maintaining tension of a separator during stack manufacturing.

Technical proposal

In order to achieve the above object, a battery stack manufacturing apparatus for a secondary battery according to one embodiment of the present disclosure includes: a stacking stage configured to be mounted to be capable of reciprocating in a horizontal direction and a vertical direction; a diaphragm supply portion configured to be located above the stacking table and supply a diaphragm onto the stacking table; a first multi-head portion provided at one side of an upper portion of the stacking table and configured to stack electrode plates on the separator on the stacking table moved to one side by aligning the positions of the electrode plates one by one; a second multi-head portion provided at the other side of the upper portion of the stacking table and configured to stack the electrode plates one by aligning positions of the electrode plates on the separator on the stacking table moved to the other side; and a defect inspection portion disposed between the first multi-head and the second multi-head, configured to take an image of a cell stack stacked on the stacking table every time the stacking table moves between the first multi-head and the second multi-head, and determine whether the cell stack is defective based on image information of the cell stack.

A battery stack manufacturing apparatus for a secondary battery according to another embodiment of the present disclosure includes: a stacking stage configured to be mounted to be capable of reciprocating in a horizontal direction and a vertical direction; a diaphragm supply portion configured to be located above the stacking table and supply a diaphragm onto the stacking table; a first multi-head portion provided at one side of an upper portion of the stacking table and configured to stack electrode plates on the separator on the stacking table moved to one side by aligning the positions of the electrode plates one by one; and a second multi-head portion provided at the other side of the upper portion of the stacking stage and configured to stack the electrode plates one by aligning positions of the electrode plates on the separator on the stacking stage moved to the other side, wherein the separator supply portion includes a plurality of rollers configured to guide the separator, a rotating portion between the plurality of rollers and the stacking stage and rotating around a center, and a pair of tension adjusting rollers mounted at both ends of the rotating portion and configured to guide the separator between the plurality of rollers and the stacking stage, and the rotating portion periodically rotates in a forward direction and a reverse direction according to an interval between the stacking stage and the rotating portion.

Advantageous effects

In the stack manufacturing apparatus for a secondary battery according to the present disclosure, the electrode plates are alternately stacked on the separator while the stacking table moves between the first electrode plate supply part and the second electrode plate supply part, and the defect inspection part may photograph an image of the battery stack stacked on the stacking table every time the stacking table moves between the first electrode plate supply part and the second electrode plate supply part.

Accordingly, it is possible to quickly and accurately determine whether the stack is defective based on image information of electrode plates stacked on the stack during the manufacturing of the stack, and to discard the defective stack immediately before the completion of the stack, thereby improving productivity, and it is possible to manufacture a high-speed and high-precision stack.

Further, the stack manufacturing apparatus for a secondary battery according to the present disclosure periodically rotates the rotating rod equipped with a pair of tension adjusting rollers for guiding the separator in the forward and reverse directions according to the distance from the stacking table, so that the tension of the separator can be uniformly maintained even if the stacking table is moved during the stack manufacturing.

Therefore, it is possible to improve production efficiency by preventing the separator from being torn and preventing the electrode plates from being incorrectly stacked on the separator, thereby producing a high-precision battery stack.

Drawings

Fig. 1 is a front view illustrating a stack manufacturing apparatus for a secondary battery according to an embodiment of the present disclosure.

Fig. 2 is a schematic view schematically illustrating a battery stack manufacturing process of a secondary battery according to an embodiment of the present disclosure.

Fig. 3 is a schematic view schematically showing a main part of a cell stack manufacturing apparatus for a secondary battery according to an embodiment of the present disclosure.

Fig. 4 is a front view illustrating a main part of a stack manufacturing apparatus for a secondary battery according to an embodiment of the present disclosure.

Fig. 5 and 6 are perspective views illustrating main parts of a stack manufacturing apparatus for a secondary battery according to an embodiment of the present disclosure from different angles.

Fig. 7 is a plan view illustrating a multi-head and a visual part included in a battery stack manufacturing apparatus for a secondary battery according to an embodiment of the present disclosure.

Fig. 8 is a plan view illustrating a multi-head and defect inspection portion included in a battery stack manufacturing apparatus for a secondary battery according to an embodiment of the present disclosure.

Fig. 9 is a side view illustrating a defect inspection portion included in a battery stack manufacturing apparatus for a secondary battery according to an embodiment of the present disclosure.

Fig. 10 is a schematic view sequentially illustrating a process of supplying a separator by a stack manufacturing apparatus for a secondary battery according to an embodiment of the present disclosure.

Fig. 11 is a schematic view sequentially illustrating a process of stacking electrode plates by a stack manufacturing apparatus for a secondary battery according to an embodiment of the present disclosure.

Detailed Description

Hereinafter, the present embodiment will be described in detail with reference to the accompanying drawings. However, the scope of the spirit of the present embodiment can be determined according to the disclosure in the present embodiment, and it can be said that the spirit of the present embodiment includes implementation modifications such as addition, deletion, and change of components to the proposed embodiment.

Fig. 1 is a front view illustrating a stack manufacturing apparatus for a secondary battery according to an embodiment of the present disclosure, and fig. 2 is a schematic view schematically illustrating a stack manufacturing process of a secondary battery according to an embodiment of the present disclosure.

As shown in fig. 1, the stack manufacturing apparatus for a secondary battery according to the embodiment of the present disclosure includes a first electrode plate supply part 10, a second electrode plate supply part 20, a separator supply part 30, a stack part 100, a hot pressing part 40, a cutting part 50, a sealing part 60, and an unloading part 70.

The first electrode plate supply part 10 and the second electrode plate supply part 20 unwind the rolls wound with the electrodes, cut the rolls into the electrode plates B1 and B2 of a predetermined length, respectively, and may supply the electrode plates B1 and B2 one by one in the stack part 100. Of course, the electrode plates B1 and B2 supplied by the first and second electrode plate supply parts 10 and 20 may be positive or negative electrode plates, and the first and second electrode plate supply parts 10 and 20 may supply the electrode plates B1 and B2 to the stacking part 100.

The separator supply part 30 may be disposed between the first electrode plate supply part 10 and the second electrode plate supply part 20, and may unwind a roll obtained by winding the separator a, thereby supplying the unwound roll to the stacking part 100 with uniform tension.

According to this embodiment, the diaphragm supply portion 30 may be composed of a plurality of rollers for guiding the diaphragm a and a guide portion, which will be described in detail below.

The stacking part 100 is disposed at the lower side of the separator supply part 30, and may be configured to repeat the process of folding the separator a supplied by the separator supply part 30 and stacking the electrode plates B1 and B2 supplied by the first and second electrode plate supply parts 10 and 20 on the separator a.

Further, the stacking portion 100 is configured to adjust the positions of the electrode plates B1 and B2 before stacking the electrode plates B1 and B2 on the separator a so that the electrode plates B1 and B2 can be stacked at the correct positions of the separator a, and to determine the electrode plates as defective and discard the electrode plates when the electrode plates B1 and B2 are stacked away from the reference position of the separator a, which will be described in detail below.

Meanwhile, the battery stack in which the electrode plates B1 and B2 are stacked between the separators a may be transferred between the stacking portion 100, the hot pressing portion 40, the cutting portion 50, and the sealing portion 60 in a state of being clamped by a clamp (not shown).

The hot pressing part 40 may be disposed at one side of the stacking part 100, and may press the electrode plates B1 and B2 by simultaneously applying heat and pressure to the cell stack transferred by the holder.

According to this embodiment, the heat pressing portion 40 includes upper/lower plates spaced apart in the vertical direction, and at least one of the upper/lower plates is installed to be able to rise/fall, and the upper/lower plates are configured to be able to generate heat.

The cutting part 50 may be disposed at one side of the hot pressing part 40, and may cut the separator a of the cell stack pressed by the hot pressing part.

According to this embodiment, the cutting part 50 includes an upper die and a lower die, and the upper die is installed to be capable of ascending/descending using a sub-motor and a cam, and the separator of the cell stack located between the upper die and the lower die can be cut while the upper die/lower die are engaged with each other.

In this case, the upper/lower molds have shapes such as a punch and a stripper on opposite surfaces so that the separator of the cell stack can be cut into a desired shape.

The sealing part 60 may be provided at one side of the cutting part 50, and may press the separator a by simultaneously applying heat and pressure to the separator a of the cell stack cut by the cutting part 50.

When the battery stack device of the secondary battery configured as described above is used, the electrode plates B1 and B2 are stacked between the separators a folded in a zigzag shape as shown in fig. 2, and the electrode plates B1 and B2 are adhered and fixed by applying heat and pressure in the up/down direction of the battery stack (C) configured with the separators.

Next, when the separator a of the cell stack C is cut into a desired shape, and heat and pressure are applied in the vertical direction of the cell stack C to further press the separator a, the cell stack C is completed.

Fig. 3 is a schematic view schematically illustrating main parts of a stack manufacturing apparatus for a secondary battery according to an embodiment of the present disclosure, fig. 4 to 6 are front and perspective views illustrating main parts of a stack manufacturing apparatus for a secondary battery according to an embodiment of the present disclosure, fig. 7 to 8 are plan views illustrating a multi-head, a visual part, and a defect inspection part included in a stack manufacturing apparatus for a secondary battery according to an embodiment of the present disclosure, and fig. 9 is a side view illustrating a defect inspection part included in a stack manufacturing apparatus for a secondary battery according to an embodiment of the present disclosure.

The main parts of the stack manufacturing apparatus for the secondary battery according to the embodiment of the present disclosure include a first loading part 11, a second loading part 21, a separator supply part 30, and a stacking part 100, and the stacking part 100 includes a stacking table 110, first and second multi-heads 120 and 130, first and second vision parts 140 and 150, and first and second defect inspection parts 170 and 180.

The first loading part 11 and the second loading part 21 may be configured to be able to transfer the electrode plates B1 and B2 supplied from the first electrode plate supply part 10 and the second electrode plate supply part 20 (shown in fig. 1) one by one. The first loading part 11 may be located at the left side, the second loading part 21 may be located at the right side, and the first loading part 11 and the second loading part 21 may be configured to face each other.

The first loading part 11 and the second loading part 21 may include adsorption plates 11a and 21a capable of adsorbing the thin electrode plates B1 and B2 to the lower side, and transfer parts 11B and 21B capable of reciprocating the adsorption plates 11a and 21a in the horizontal and vertical directions, but are not limited thereto.

The diaphragm supply portion 30 is located between the first loading portion 11 and the second loading portion 21, and may be configured to supply the diaphragm a with uniform tension.

In detail, the diaphragm supply portion 30 may include a driving roller 31, first and second idle rollers 32a and 32b, a tension roller 33, a guide roller 34, a rotating portion 35, first and second tension adjusting rollers 36a and 36b, and first to fourth guide portions 37a, 37b, 38a and 38b, but is not limited thereto.

The driving roller 31 is a portion to which a diaphragm roller around which the diaphragm a is wound is attached, and is disposed at the uppermost side. The first idle roller 32a and the second idle roller 32b are located at one side of the driving roller 31 and installed at a predetermined interval. The tension roller 33 is located at the lower side between the first idle roller 32a and the second idle roller 32b, and when the tension roller 33 is installed to be movable in the vertical direction, the tension of the diaphragm a can be adjusted.

The rotating portion 35 is located below the guide roller 34 on the side of the second idle roller 32b, and may rotate in a forward direction or a reverse direction by a predetermined angle based on the center thereof. The first and second regulating rollers 36a and 36b are disposed at both sides at predetermined intervals based on the center of the rotating portion 35, and when the rotating portion 35 is periodically rotated in the forward/reverse direction, the first and second regulating rollers 36a and 36b may periodically wind and unwind the diaphragm a guided by the first and second regulating rollers 36a and 36 b. Of course, the operation of the rotating portion 35 is linked with the movement of the stacking table 110, which will be described in detail below.

The first and second guide portions 37a and 37b are disposed side by side under the rotating portion 35, and the third and fourth guide portions 38a and 38b are disposed side by side under the first and second guide portions, with the diaphragm a sandwiched between the first and second guide portions 37a and 37b and the third and fourth guide portions 38a and 38b to be guided to the stacking table 110. The first to fourth guide portions 37a, 37b, 38a, 38b may be configured in plural, or may be configured in various ways, for example, in the form of rollers.

The stacking table 110 provides a space in which the power supply electrode plates are stacked on the separator a, and may include a horizontal driving portion 111 for reciprocating the stacking table 110 in a horizontal direction between the first multi-head 120 and the second multi-head 130, and a vertical driving portion 112 for reciprocating the stacking table 110 in a vertical direction to the first multi-head 120 and the second multi-head 130.

In addition, the stacking table 110 is provided with a clamp (J) to fold the diaphragm (a) supplied thereto from left to right, and four clamps (J1 to J2) for holding the diaphragm (a) in the left, right, front and rear directions may be provided.

When the electrode plate B1 is stacked on the separator a on the stacking table 110 from the left side, the stacking table 110 can move in the right direction in a state where the two jigs J1 and J2 located on the right side of the stacking table 110 in the front-rear direction press the separator a. Further, when the electrode plate B2 is stacked on the separator a on the stacking table 110 from the right side, the stacking table 110 can move in the left direction in a state where the two jigs J3 and J4 located on the left side of the stacking table 110 in the front-rear direction press the separator a.

By repeating the above-described process, a battery stack in which the separator a is folded in the opposite direction from left to right and the electrode plates B1 and B2 are stacked between the folded separators a can be manufactured.

The first multi-head 120 is located under the first loading part 11, and the electrode plate B1 received from the first loading part 11 may be supplied onto the stacking table 110 moved to the lower side of the first multi-head 120.

The first multi-head 120 includes a first adsorption plate 121 capable of vacuum-adsorbing the electrode plate B1, and four first adsorption plates 121 may be disposed at the top, bottom, left, and right sides. In addition, the first multi-head 120 may include a driving motor (not shown) for rotating the first adsorption plate 121 toward the upper side, the left side, the lower side, and the right side in this order.

The first multi-head 120 may correct the position of the first adsorption plate 121 according to a measurement result of the first vision part 140, which will be described below.

According to this embodiment, the first multi-head 120 may include: a Y-axis correcting portion 122 that moves the first suction plate 121 in the front-rear direction of the stacking table 110; and a θ -axis correcting portion 123 that rotates the first suction plate 121 about a rotation axis perpendicular to the upper surface of the stacking table 110, and the Y-axis correcting portion 122 and the θ -axis correcting portion 123 may be configured in the form of sub-motors capable of moving the first suction plate 121, but are not limited thereto.

Of course, the first multi-head 120 may further include an X-axis correction portion for moving the first suction plate 121 in the left-right direction of the stacking table 110, but the position of the stacking table 110 may be configured to be corrected in the left-right direction, and the X-axis correction portion may be omitted.

The second multi-head 130 may be located under the second loading part 21, and may supply the electrode plate B2 received from the second loading part 21 on the stacking table 110 moved to the lower side of the second multi-head 130.

Similar to the first multi-head 120, the second multi-head 130 is configured to include a driving motor (not shown), a Y-axis correcting portion 132, and a θ -axis correcting portion 133 in addition to the second adsorption plate 131, and a detailed description thereof will be omitted. However, the second multi-head 130 is configured to rotate the second adsorption plate 131 toward the upper side, the right side, the lower side, and the left side in this order, and may be disposed to face the first multi-head as a whole.

The first and second vision portions 140 and 150 are disposed to be spaced apart from both sides of the first and second multi-heads 120 and 130, and positions of the electrode plates B1 and B2 transferred by the first and second multi-heads 120 and 130 may be aligned.

The first vision part 140 is a camera mounted to face the first suction plate 121 of the left side of the first multi-head 120, and may capture an edge image of the electrode plate B1 mounted on the first suction plate 121 of the left side of the first multi-head 120, and correct the captured edge image of the electrode plate B1 according to the reference position.

The first vision part 140 may control the operations of the Y-axis correction part 122 and the θ -axis correction part 123 included in the first multi-head part 120 so as to align the positions of the electrode plates B1 supplied to the stacking table 110 by the first multi-head part 120.

The second vision part 150 is a camera mounted to face the second suction plate 131 on the right side of the second multi-head 130, and may capture an edge image of the electrode plate B2 mounted on the second suction plate 131 on the right side of the second multi-head 130, and correct the captured edge image of the electrode plate B2 according to the reference position.

The second vision part 150 may control the operations of the Y-axis correcting part 132 and the θ -axis correcting part 133 included in the second multi-head part 130 so as to align the positions of the electrode plates B2 supplied to the stacking table 110 by the second multi-head part 130.

The first and second defect-inspecting parts 160 and 170 are disposed side by side at the lower part between the first and second multi-heads 120 and 130, and when the stack table 110 moves in the left-right direction, defects in the cell stack located on the stack table 110 can be determined.

The first defect inspection portion 160 is configured to photograph the upper surface of the stacking stage 110 moving from the first multi-head 120 to the second multi-head 130 (i.e., left to right) to compare the edge image information of the electrode plate B1 supplied from the first multi-head 160 with a reference position to determine a defect thereof.

The first defect inspection portion 160 may include: a line scanning camera 161 which can continuously photograph the moving stack table 110; a reflection plate 162 that reflects light of the line scanning camera 161 toward an upper side of the stack table 110; and a control section 163 that compares the edge image information of the uppermost electrode plate B1 of the cell stack photographed by the line scanning camera 161 with a reference position to determine whether it is defective, and controls the transfer of the cell stack according to whether it is defective.

The second defect inspection part 170 is configured to photograph the upper surface of the stacking stage 110 moving from the second multi-head 130 to the first multi-head 120 (i.e., right to left), and compares edge image information of the electrode plate B2 supplied from the second multi-head 130 with a reference position to determine defects thereof, and similarly may include a line scanning camera 171, a reflection plate 172, and a control part 173.

The first and second defect inspection portions 160 and 170 may capture and accumulate images of the same electrode plates B1 and B2 for each type of electrode plates B1 and B2 and determine whether each type of electrode plates B1 and B2 are defective. The plurality of first and second defect-inspecting parts 160 and 170 may be provided according to the types of the electrode plates B1 and B2, and the types of the electrode plates B1 and B2 may be variously classified into cathodes, anodes, shapes, sizes, and the like.

As shown in (a), when the electrode plate B1 is stacked on the separator a from the left side of the stacking table 110, and then the stacking table 110 is moved from the left side to the center as shown in (B), the separator (a) may be released; however, when the rotating portion 35 rotates counterclockwise and the diaphragm a guided by the first dancer roller 36a and the second dancer roller 36b is pulled, the tension of the diaphragm a may be kept constant.

As shown in (c), the diaphragm a may be pulled when the stacking table 110 moves from the center to the right; however, when the rotating portion 35 rotates clockwise and the diaphragm a guided by the first tension adjusting roller 36a and the second tension adjusting roller 36b is released, the tension of the diaphragm a may be kept constant.

As shown in (d), when the electrode plate B2 is stacked on the separator a from the right side of the stacking table 110, and then the stacking table 110 is moved from the right side to the center as shown in (e), the separator (a) may be released; however, when the rotating portion 35 rotates counterclockwise and the diaphragm a guided by the first dancer roller 36a and the second dancer roller 36b is pulled, the tension of the diaphragm a may be kept constant.

As shown in (f), when the stacking table 110 moves leftward from the center, the diaphragm a may be pulled; however, when the rotating portion 35 rotates clockwise and the diaphragm a guided by the first tension adjusting roller 36a and the second tension adjusting roller 36b is released, the tension of the diaphragm a may be kept constant.

As described above, the rotating portion 35 may be interlocked with the stacking table 110. In other words, the rotating part 35 is periodically rotated clockwise or counterclockwise at a predetermined angle according to the interval between the stacking table 110 and the rotating part 35, and the tension of the diaphragm a can be uniformly adjusted even if the stacking table 110 is moved in the left-right direction.

Therefore, it is possible to improve production efficiency by preventing the separator a from being torn, and it is possible to prevent the electrode plates B1 and B2 from being incorrectly stacked on the separator a, thereby producing a high-precision battery stack.

As shown in (a), one sheet of electrode plates B1 and B2 is adsorbed to the lower sides of the loading parts 11 and 21, and when the loading parts 11 and 21 descend to the upper sides of the multi-heads 120 and 130, as shown in (B), the electrode plates B1 and B2 may be adsorbed to the adsorption plates 121 and 131 located at the upper sides of the multi-heads 120 and 130.

When the multi-heads 120 and 130 are rotated by 90 °, as shown in (c), the adsorption plates 121 and 131, to which the electrode plates B1 and B2 are adsorbed, face the vision parts 140 and 150 on one side, and the vision parts 140 and 150 take edge images of the electrode plates B1 and B2 to compare the edge images of the electrode plates B1 and B2 with the reference positions, and then align the electrode plates B1 and B2 to the reference positions.

In order to align the electrode plates B1 and B2 to the reference position, the adsorption plates 121 and 131, which adsorb the electrode plates B1 and B2, may move in the Y-axis direction or rotate in the θ -axis direction, and the stacking table 110, on which the electrode plates B1 and B2 are stacked, may move in the X-axis direction.

When the multi-heads 120 and 130 are rotated by 90 °, the suction plates 121 and 131 aligned with the reference positions as shown in (d) face the stacking table 110 of the lower side, and when the stacking table 110 is lifted in a state where the separator a is folded by the jigs J1 to J4 (as shown in fig. 5) on the stacking table 110, the stacking table 110 receives the electrode plates B1 and B2 separated from the suction plates 121 and 131 on the separator a and stacks the electrode plates B1 and B2, and then lowers the stacking table 110 as shown in (e).

Since the multi-heads 120 and 130 have four adsorption plates 121 and 131, the process of continuously supplying and aligning the electrode plates B1 and B2 can be repeated even if the multi-heads 120 and 130 are rotated by 90 °, and the stack processing time can be shortened.

As shown in fig. 3, the same process as described above is performed in the respective multi-headed parts 120 and 130 located at the left and right sides, and the electrode plates B1 and B2 are alternately stacked while the stacking table 110 reciprocates between the respective multi-headed parts 120 and 130.

The defect inspection portions 160, 170 take edge images of the electrode plates B1 and B2 located at the uppermost side of the stack table 110 while the stack table 110 reciprocates between the respective multi-headed portions 120 and 130, and determine defects according to the reference positions and the comparison results.

When it is determined that the stack is defective through the defect inspection parts 160 and 170, the process of placing the electrode plates B1 and B2 into the multi-heads 120 and 130 is stopped, and the stack determined to be defective is discarded after the separator is cut.

On the other hand, if it is determined that the cell stack is good by the defect-checking parts 160 and 170, the process of putting the electrode plates B1 and B2 into the multi-heads 120 and 130 to stack the electrode plates B1 and B2 on the stacking table 110 is repeated.

Of course, the stacking portion 100 (shown in fig. 1) repeats the process of stacking the electrode plates B1 and B2 and determining defects as described above until the cell stack is completed.

As described above, as shown in fig. 1, the cell stack in which all the electrode plates B1 and B2 are manufactured into a finished product sequentially passes through the hot pressing part 40, the cutting part 50, the sealing part 60, and the unloading part 70.

Therefore, it is possible to quickly and accurately determine whether the stack is defective based on the image information of the electrode plates stacked on the uppermost side of the stack during the manufacturing of the stack, and to discard the defective stack immediately before the completion of the stack, so that the productivity thereof can be improved, and a high-speed and high-precision stack can be manufactured.

Claims

1. A stack manufacturing apparatus for a secondary battery, the stack manufacturing apparatus for a secondary battery comprising:

a stacking stage configured to be capable of reciprocating in a horizontal direction and a vertical direction;

a diaphragm supply portion configured to be located above the stacking table and supply a diaphragm onto the stacking table;

a first multi-head portion provided at one side of an upper portion of the stacking table and configured to stack electrode plates on the separator on the stacking table moved to one side by aligning the positions of the electrode plates one by one;

a first loading part disposed above the first multi-head part and configured to supply the electrode plates to the first multi-head part one by one;

A second multi-head portion provided at the other side of the upper portion of the stacking table and configured to stack the electrode plates one by aligning positions of the electrode plates on the separator on the stacking table moved to the other side;

a second loading part disposed above the second multi-head part and configured to supply the electrode plates to the second multi-head part one by one; and

a defect inspection portion provided between the first multi-head and the second multi-head, configured to take an image of a cell stack stacked on the stacking table every time the stacking table moves between the first multi-head and the second multi-head, and determine whether the cell stack is defective based on image information of the cell stack,

wherein the first multi-head and the second multi-head include heads for rotating an adsorption plate fixing the electrode plate toward an upper side, one side, a lower side and the other side,

wherein the head part is provided with four adsorption plates at the upper side, one side, the lower side and the other side,

The battery stack manufacturing apparatus for a secondary battery includes:

a first vision part disposed outside the first multi-head part and configured to take an edge image of the electrode plate fixed to the adsorption plate when the adsorption plate faces one side; and

a second vision part disposed outside the second multi-head part and configured to take an edge image of the electrode plate fixed to the suction plate when the suction plate faces one side,

wherein the first multi-head and the second multi-head correct the position of the suction plate to an error value compared with a reference position for stacking the electrode plates based on edge image information of the electrode plates measured in the first vision portion and the second vision portion,

wherein the first multi-head and the second multi-head comprise:

a Y-axis correction section configured to horizontally move the suction plate in a direction orthogonal to a moving direction of the stacking table, which is an X-axis direction, by an error value based on an upper surface of the stacking table, the direction orthogonal to the X-axis direction being a Y-axis direction; and

A theta axis correction section configured to rotate the suction plate by an error value in a rotation axis direction perpendicular to an XY plane, wherein the rotation axis direction is a theta axis,

wherein the first vision part is a camera mounted to face a first suction plate of a left side of the first multi-head, and is capable of photographing an edge image of the electrode plate mounted on the first suction plate of the left side of the first multi-head, and correcting the photographed edge image of the electrode plate according to the reference position,

wherein the first vision part controls operations of the Y-axis correction part and the theta-axis correction part of the first multi-head part and aligns positions of the electrode plates,

wherein the second vision part is a camera mounted to face a second suction plate on the right side of the second multi-head, and is capable of photographing an edge image of the electrode plate mounted on the second suction plate on the right side of the second multi-head, and correcting the photographed edge image of the electrode plate according to the reference position,

wherein the second vision portion controls operations of the Y-axis correction portion and the θ -axis correction portion of the second multi-head portion and aligns positions of the electrode plates.

2. The stack manufacturing device for a secondary battery according to claim 1,

wherein the diaphragm supply portion includes:

a driving roller on which a diaphragm roller is mounted, the diaphragm roller being wound with the diaphragm;

a pair of idle rollers located on one side of the drive roller and configured to guide the separator unwound from the drive roller;

a tension roller movably mounted between the pair of idle rollers and configured to guide the diaphragm between the pair of idle rollers;

a rotating portion located at one side of a lower portion of the idle roller and configured to rotate around a center;

a pair of dancer rollers mounted at both ends of the rotating portion and configured to guide the diaphragm unwound from the pair of idle rollers; and

a pair of guide portions located below the pair of dancer rollers and configured to guide the separator unwound from the pair of dancer rollers to the stacking table in a state of being sandwiched between the pair of guide portions.

3. The stack manufacturing device for a secondary battery according to claim 2,

Wherein the rotating portion is periodically rotated in a forward direction and a reverse direction according to an interval between the stacking table and the guide portion.

4. The stack manufacturing device for a secondary battery according to claim 3,

wherein the rotating portion rotates at a predetermined angle in a direction to pull the diaphragm when the stacking table moves in a direction closer to the pair of guide portions, and rotates at a predetermined angle in a direction to unwind the diaphragm when the stacking table moves in a direction away from the pair of guide portions.

5. The stack manufacturing device for a secondary battery according to claim 1,

wherein the stacking stage is moved in the X-axis direction by an error value.

6. The battery stack manufacturing apparatus for a secondary battery according to any one of claims 1 to 5,

wherein the defect inspection section includes:

a line scanning camera configured to continuously take edge images of an uppermost electrode plate of the cell stack stacked on the stacking table while moving the stacking table; and

and a reflection plate disposed between the line scanning camera and a path through which the stacking stage moves, and configured to irradiate an upper surface of the stacking stage to the line scanning camera.

7. The stack manufacturing device for a secondary battery according to claim 6,

wherein the defect inspection section includes a control section configured to determine whether the cell stack is defective by comparing edge image information of the uppermost electrode plate of the cell stack photographed by the line scanning camera with a reference position for stacking the electrode plates, and to control the transfer of the cell stack according to whether the cell stack is defective.

8. The stack manufacturing device for a secondary battery according to claim 7,

wherein the control portion receives a reference position for stacking the electrode plates as coordinates of a plurality of reference marks provided on the stacking table.

9. The stack manufacturing device for a secondary battery according to claim 6,

wherein a plurality of defect inspection portions as many as the number of types of electrode plates supplied by the first multi-head and the second multi-head are provided, and

wherein one defect inspection section photographs and accumulates images of one type of electrode pads.

10. A stack manufacturing apparatus for a secondary battery, the stack manufacturing apparatus for a secondary battery comprising:

a second multi-head portion disposed at the other side of the upper portion of the stacking table and configured to stack the electrode plates one by aligning positions of the electrode plates on the separator moved to the other side on the stacking table; and

a second loading part disposed above the second multi-head part and configured to supply the electrode plates to the second multi-head part one by one,

Wherein the diaphragm supply portion includes:

a plurality of rollers configured to guide the diaphragm;

a rotating portion located between the plurality of rollers and the stacking table and rotating about a center; and

a pair of dancer rollers mounted at both ends of the rotating portion and configured to guide the separator between the plurality of rollers and the stacking table, and

wherein the rotating portion is periodically rotated in a forward direction and a reverse direction according to an interval between the stacking table and the rotating portion,

the battery stack manufacturing apparatus for a secondary battery includes:

wherein the first multi-head and the second multi-head comprise:

11. The stack manufacturing device for a secondary battery according to claim 10,

wherein the diaphragm supply portion includes:

a tension roller movably mounted between the pair of idle rollers and configured to guide the diaphragm between the pair of idle rollers; and

A pair of guide portions located below the pair of idle rollers and the tension roller and configured to guide the separator to the stacking table in a state of being sandwiched between the pair of guide portions, an

Wherein the rotating portion is located between the idler roller and the pair of guide portions.

12. The stack manufacturing device for a secondary battery according to claim 11,

wherein the rotating portion rotates at a predetermined angle in a direction to pull the diaphragm when the stacking table moves in a direction closer to the guide portion, and rotates at a predetermined angle in a direction to unwind the diaphragm when the stacking table moves in a direction away from the guide portion.